RU2558686C2 - Rotor for electrical machine and method for its adjustment - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to the field of electrical machines. A rotor (4) for an electrical machine (1) comprises a shaft (6), a cross-bar at the shaft (6), a multilayer drum (8) at the cross-bar. The cross-bar has a multitude of elements placed at a distance defining air ducts. The multilayer drum (8) has a multitude of cooling channels (17) connected to the air ducts. The rotor (4) has also a choke element (25) coupled to at least one air duct and/or cooling channel (17).

EFFECT: preventing the circulation of any air-flow rate exceeding the air-flow rate required for cooling.

11 cl, 9 dwg

Description

FIELD OF THE INVENTION

The present disclosure relates to a rotor for an electric machine and a method for fine-tuning it.

The electric machine may be a rotating electric machine, such as a synchronous generator or an asynchronous generator (preferably connected to a hydraulic turbine), or a synchronous or asynchronous electric motor, or also other types of electric machines. Additionally, the electric machine may have a rotor with or without distinct poles.

BACKGROUND OF THE INVENTION

Electric machines, such as hydrogenerators, have a rotor connected to a turbine and a stator. Often the rotor and stator are assembled with a vertical axis.

The rotor comprises a shaft, a cross on the shaft and a multilayer drum on the cross.

The spider defines a plurality of axial ducts, and the multilayer drum has a plurality of radial cooling channels connected to the air ducts, so that gas (such as air) during operation circulates through the air ducts and cooling channels to cool the rotor and stator.

Air circulation causes losses that must be minimized.

In particular, the losses depend on the total volumetric flow rate of air circulating through the machine and the distribution of the volumetric flow rate of air in the machine.

To reduce losses during circulation, electric machines are traditionally designed in such a way as to optimize the circulation of air volume, however, when designing the cooling characteristics of such electric machines, there are some uncertainties that cannot be calculated in advance.

SUMMARY OF THE INVENTION

One aspect of this disclosure includes providing a rotor for an electric machine and an indication of a rotor refinement method that can reduce circulation losses.

These and other aspects are achieved by providing a rotor and method in accordance with the attached claims.

Advantageously, the rotor and method also provide temperature optimization.

BRIEF DESCRIPTION OF THE DRAWINGS

Additional features and advantages will become more apparent from the description of the preferred, but not exclusive, embodiment of the rotor and method, illustrated by means of a non-limiting example in the accompanying drawings, in which:

FIG. 1 is a schematic view of an electric machine in a first embodiment;

in FIG. 2 and 3 show details of the electric machine of FIG. one;

FIG. 4 is a schematic view of an electric machine in a second embodiment;

FIG. 5-8 depict details of the electric machine of FIG. one; and

FIG. 9 shows another embodiment of an electric machine.

DETAILED DESCRIPTION OF EMBODIMENTS

The drawings show such an electric machine 1, such as a hydrogenerator.

The electric machine 1 has a stator 2 with a stator bore 3 and a rotor 4 located in the stator bore 3.

The stator 2 and rotor 4 are housed in a housing that contains a gas, such as air (but other gases are also possible). The gas contained in the housing circulates through the electric machine 1 to cool it.

The rotor 4 includes a shaft 6, which serves as a support for the crosspiece 7. The crosspiece 7 serves as a support for the multilayer drum 8, which includes a mechanical part 9 and an electric part 10 with grooves accommodating conductive rods 11.

The spider 7 has a plurality of spaced-apart elements 13, for example radial plates, which define air ducts 14 between each other.

Preferably, the ducts 14 extend parallel to the longitudinal axis 15 of the rotor.

The multilayer drum 8 has cooling channels 17, which preferably extend radially and perpendicular to the axis 15 of the rotor 15.

The cooling channels 17 are connected to the ducts 14.

The stator 2 has a multilayer core 19 and cooling channels 20. The multilayer core is connected to the support 21 and the cooler 22.

The rotor contains throttle elements 25, which are connected with one or more ducts 14 and / or one or more cooling channels 17.

The throttle elements 25 control the total volumetric flow rate of air circulating through the electric machine 1 and the distribution of the volumetric flow rate of air in the machine, so that circulation losses can be optimized.

For example, the volumetric flow rate of air can be adjusted so that the volumetric flow rate of air circulating through the machine (for example, the rotor and stator) is the volumetric flow rate of air required for cooling; in other words, through the electric machine 1, the circulation of any volumetric air flow in excess of the volumetric air flow required for cooling is prevented.

The throttle elements 25 may be provided in the ducts 14.

In this case, the throttling elements preferably set the boundaries of the first zone 27 of the duct 14 connected to the first group 28 of cooling channels 17 and the second zone 29 of the duct 14 connected to the second group 30 of cooling channels 17.

For example, the throttle elements 25 may be defined by the plates provided in the duct 14, the plate defining a passage 31 for gas passing through the duct 14.

The passage 31 is preferably defined by a hole in the plate.

As an option or addition, the throttle element in this embodiment may also be any element by which the air volumetric flow rate can be throttled, for example, throttle valves with electric, hydraulic or pneumatic control.

As an option or addition to the throttle elements, which partially cover the duct 14, the throttle elements can also be provided at the cooling channels 17.

In this case, the throttle elements 25 are preferably located in the ducts 14 and connected to the ends of at least some of the cooling channels 17.

For example, throttle elements 25 include one or more walls 35 movable with respect to the multilayer drum 8. Each wall 35 may be an elongated plate that is placed in the duct 14 and can slide along the multilayer drum 8.

Each wall 35 has slots 36 and is connected to the actuation system, which is schematically represented at number 37.

The actuation system 37 can adjust the position of the wall 35 so that the slots 36 align with the cooling channels 17 or partially or completely cover them.

As an option or addition, the throttle element in this embodiment may also be any element by which the air volumetric flow rate can be throttled, for example, throttle valves with electric, hydraulic or pneumatic control, connected to each cooling channel 17.

The cooling channels 17 may also have an end connected to the ducts 14, which expands and is preferably provided with a throttle element 25 at its larger diameter.

In this embodiment, the control of the throttle elements 25 controls the pressure loss at the inlet to the cooling channels 17, so that, for example, with fully open throttle elements 25, more flow through the cooling channels is achieved than with partially open throttle elements 25 or even without any system air adjustment.

Also in this case, the throttle elements 25 can be, for example, throttle valves with electric, or pneumatic, or hydraulic actuators. However, throttle elements of other types are possible.

The operation of the electric machine is obvious from the described and illustrated, and looks essentially as follows.

During operation, a cooling gas, such as air, enters the air ducts 14, passes through the air ducts 14 and enters the cooling channels 17 for cooling the conductive rods 11 and the multilayer drum 8. Then, the cooling gas passes into the cooling channels 20 of the stator 2 also for cooling the stator rods and a multilayer core 19 of the stator.

Thus, the cooling gas enters the cooler 22 for cooling.

Arrow F indicates air circulation.

During circulation, throttle elements 25 limit the volumetric air flow through the machine, so that only the volume of air required for cooling is actually circulated. This limits circulation losses.

The present disclosure also relates to a method for upgrading a rotor for an electric machine.

The method includes providing at least a throttle element 25 connected to at least one duct 14 and / or a cooling channel 17.

For example, the rotor 4 is operated before the throttle elements 25 are provided. While the rotor is operating (before the throttle elements 25 are provided), air circulation losses and / or heat losses are detected.

Thus, the throttle elements 25 are provided based on detectable losses during air circulation and / or heat losses (for example, to minimize losses during circulation and / or optimize temperatures).

Naturally, the described features can be provided independently of each other.

In practice, the materials and sizes used can be arbitrarily selected in accordance with the requirements and state of the art.

REFERENCE DIGITAL POSITIONS

1 electric car

2 stator

3 stator boring

4 rotor

6 shaft

7 cross

8 multi-layer drum

9 mechanical

10 electrical part

11 conductive rods

13 elements

14 ducts

15 rotor axis

17 cooling channels

19 multilayer core

20 cooling channels

22 cooler

25 throttle elements

27 first zone

28 first group

29 second zone

30 second group

31 pass

35 wall

36 slit

37 actuation system

F cooling gas

Claims (11)

1. The rotor (4) for an electric machine (1), comprising a shaft (6), a spider (7) on a shaft (6), a multilayer drum (8) on a spider (7), and the spider (7) has many spaced radial plates (13) between which air ducts (14) are formed, the multilayer drum (8) having a plurality of cooling channels (17) connected to the air ducts (14), the rotor comprising at least one throttling regulator (25), associated with at least one duct (14) and / or cooling channel (17) and containing:
at least one wall (35) movable relative to the multilayer drum (8),
slots (36) on at least one wall (35),
a system (37) for actuating at least one wall (35), which provides adjustment of the position of the wall (35), so that the slots (36) are aligned with the cooling channels 17 or partially or completely cover them. 2. The rotor (4) according to claim 1, wherein at least one throttling regulator (25) is provided in at least one duct (14). 3. The rotor (4) according to claim 2, in which at least one throttle controller (25) determines:
the first zone (27) of the air duct (14) connected to the first group (28) of cooling channels (17), and the second zone (29) of the air duct (14) connected to the second group (30) of cooling channels (17). 4. The rotor (4) according to claim 2, in which at least one throttling regulator (25) is a plate provided in the duct (14), and the plate defines a passage (31) for gas passing through the duct (14) ) 5. The rotor (4) according to claim 4, in which the passage (31) is determined by the hole in the plate. 6. The rotor (4) according to claim 1, wherein at least one throttling regulator (25) is provided at least one cooling channel (17). 7. The rotor (4) according to claim 6, in which at least one throttling regulator (25) is placed in at least one duct (14) and connected to the end of at least one cooling channel (17) ) 8. The rotor (4) according to claim 1, wherein the at least one throttling regulator includes a throttling valve. 9. The rotor (4) according to claim 8, in which the throttling valve is a throttling valve with electric, hydraulic or pneumatic control. 10. A method for fine-tuning the rotor (4) for an electric machine (1), the rotor comprising a shaft (6), a spider (7) on a shaft (6), a multilayer drum (8) on a spider (7),
moreover, the crosspiece (7) is performed with a plurality of radial plates (13) located at a distance, between which air ducts (14) are formed,
moreover, a multilayer drum (8) is performed with a plurality of cooling channels (17) connected to the air ducts (14), while at least one throttle controller (25) is connected to at least one air duct (14) and / or a cooling channel (17), wherein at least one wall (35) of the throttle controller (25) is movable relative to the multilayer drum (8),
form slots (36) on at least one wall (35), install on the throttle controller (25) a system (37) for actuating at least one wall (35),
adjust the position of the wall (35), so that the slots (36) are aligned with the cooling channels (17) or partially or completely cover them. 11. The method according to p. 10, containing stages in which:
operate the rotor (4) before installing the throttle controller (25), and
register losses during air circulation and / or heat losses during operation of the rotor (4),
set the throttling controller (25) based on the detected losses during air circulation and / or heat loss.

Images